Use of Remote-Sensing to Quantify the Distribution of Progradation/erosion Along a Forced-Regressive Modern Coastline: Driving Factors and Impact on the Stratigraphic Record

The Sedimentary Record Pub Date : 2023-02-14 DOI:10.2110/001c.70239

V. Zuchuat, M. Poyatos‐Moré, B. Nyberg, R. Nanson, S. Sagar, L. Lymburner, Robbi Bishop-Taylor

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引用次数: 1

Abstract

The long-term development of ancient and modern coastal distributive fluvial systems (DFSs) during periods of relative sea-level highstand or fall usually drives net-progradation of shorelines. Such systems often develop in periods of relative sea-level highstand or fall and typically record annual to millennial-scale deviations in coastal trajectories. A new continental dataset (Digital Earth Australia Coastlines: DEA Coastlines) provides an opportunity to examine such variations in coastal behaviour over annual to decadal scales (1988-2019) at local to continental spatial scales. This dataset is herein applied to the 655 km coastline fronting Australia’s largest amalgamated coastal distributive fluvial systems, which is situated in the epicontinental seaway of the Gulf of Carpentaria in the north of the continent. Despite the overall forced regressive conditions (i.e. progradation during relative sea-level fall), only 54% of this coastlines length net-prograded, whereas 47% was eroded. Though temporal cyclicity in progradation and erosion is evident along segments of this coast, these patterns could not be correlated with either the Southern Oscillation Index (R2 = -0.20) or rainfall (R2 = 0.24). Instead, short-term coastline dynamics appear to be the result of complex interactions between fluvial, wave, longshore current, and tidal processes. The high-resolution DEA Coastlines dataset highlights the diachronous, heterochronous, composite, and amalgamated nature of net-progradational stratigraphic strata that can develop in shallow-marine environments where hinge-points between prograding and retrograding coastal segments are dynamic features that migrate with time. Our conclusions show that shorelines display granular temporal and spatial deviations in coastal trajectory, with contemporaneous progradation and erosion occurring over 1-100 km length scales. This is significantly more heterogeneity than previously envisaged, thereby suggesting the need for updating models of coastal systems.

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利用遥感量化强迫退变现代海岸线的进退/侵蚀分布:驱动因素及其对地层记录的影响

古今沿海分布河流系统在相对海平面上升或下降期间的长期发展，通常会推动海岸线的净进积。这样的系统通常在相对海平面上升或下降的时期发展，通常记录了沿海轨迹每年到千年尺度的偏差。一个新的大陆数据集(数字地球澳大利亚海岸线:DEA海岸线)提供了一个机会，可以在地方到大陆的空间尺度上，在年至年代际尺度(1988-2019)上研究沿海行为的这种变化。此数据集在此应用于澳大利亚最大的合并海岸分布河流系统前655公里的海岸线，该系统位于大陆北部的卡奔塔利亚湾的陆表海道。尽管总体上存在强迫退退条件(即相对海平面下降期间的退退)，但只有54%的海岸线长度净退退，而47%的海岸线被侵蚀。虽然该海岸的进积和侵蚀的时间周期性很明显，但这些模式与南方涛动指数(R2 = -0.20)或降雨量(R2 = 0.24)都不相关。相反，短期海岸线动态似乎是河流、波浪、岸流和潮汐过程之间复杂相互作用的结果。高分辨率DEA海岸线数据集强调了净退积地层的历时性、非时性、复合性和合并性，这些地层可以在浅海环境中发育，其中退积和退积海岸段之间的拐点是随时间迁移的动态特征。我们的结论表明，海岸线在海岸轨迹上呈现粒状的时空偏差，同时期的进积和侵蚀发生在1-100 km的长度尺度上。这比以前设想的更加不均匀，因此表明需要更新沿海系统的模式。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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The Sedimentary Record

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